Server device, image transmission method, terminal device, image reception method, program, and image processing system

ABSTRACT

In some embodiments, methods and apparatus are provided for transmitting, via at least one network, a request to another apparatus for still image data generated from moving image data, the request comprising at least one criterion, and receiving still image data generated from moving image data matching the at least one criterion in the request. In further embodiments, methods and apparatus are provided for receiving the request via at least one network, using the at least one criterion in the request to obtain still image data generated from moving image data, and responding to the request by transmitting the obtained still imagedata.

TECHNICAL FIELD

The present invention relates to a server device, image transmissionmethod, terminal device, image reception method, program, and imageprocessing system, and particularly relates to a server device and soforth that handles high quality still images generated from a movingimage by image processing.

BACKGROUND ART

In general, a so-called funduscopy, by which observation of the fundussuch as the retina and optic disc and so forth within the eye, via thepupil, is performed. A funduscopy is performed using a specializeddevice such as a funduscope or fundus camera. For example, an observerphotographs the fundus within the eye of a subject, which is theobservation target, with a fundus camera, displays the obtained fundusimage on a monitor or the like, and performs observation.

Also, the image data of the fundus image thus photographed and obtainedwith a fundus camera may be saved in storage such as an HDD (Hard DiskDrive), and used for discussion thereafter or explanation to a patientand so forth. For example, PTL 1 discloses that, as image data of amedical image, not only still image data, but moving image data may besaved. For example, in order to show endoscopy images to a patient,description is difficult with just still images, so display of movingimages is also enabled.

CITATION LIST Patent Literature

-   PTL 1: JP 2005-044004A

SUMMARY OF INVENTION Technical Problem

A fundus camera normally photographs still images. In order to moreaccurately perform observation of a fundus image, the fundus image hasto have a higher image quality. In order to improve the image quality ofthe fundus image, photographing a moving image with a fundus camera,performing image processing as to this moving image to generate stillimages, thereby improving the image quality, can be conceived. In thiscase, if the medical institutions individually perform image processing,in the event that a new processing algorithm has been developed, thehardware or software (processing program) has to be individuallyupdated, resulting in a high cost for updates.

An object of the present technology is to enable obtaining still imagesof higher quality fundus images and the like in medical institutions orthe like at a low cost, for example.

Solution to Problem

According to some embodiments of the present disclosure, an apparatus isprovided, comprising at least one processor programmed to: receive, viaat least one network, a request from another apparatus for still imagedata generated from moving image data, the request comprising at leastone criterion; use the at least one criterion in the request to obtainstill image data generated from moving image data; and respond to therequest by transmitting the obtained still image data. According to somefurther embodiments of the present disclosure, a server device isprovided, including an image processing unit to generate still imagedata from moving image data stored in a storage unit, wherein aprocessing program can be automatically updated or added thereto;

a search information receiving unit to receive search informationtransmitted from a terminal device;

and an image transmission unit to transmit, to the terminal device,still image data generated by processing predetermined moving image datausing a predetermined processing program, such still image datacorresponding to search information received by the search informationreceiving unit.

According to some embodiments of the present technology, still imagedata may be generated from moving image data stored in a storage unit byan image processing unit. The image processing unit can automaticallymodify or add a processing program. For example, the modification oraddition of a processing program is performed in the event that a newprocessing algorithm is developed, i.e. in the event that a versionupdated to the processing program becomes available. For example, withthe image processing unit, one or more of NR (noise reduction),sharpness improvement, and DR (dynamic range)improvement is executed,and high quality still image data is generated.

The moving image data stored in the storage unit is transmitted from aterminal device that is the same or different from the terminal device,via a network, for example. However, the moving image data may also beprovided by a removable memory or the like. Also, for example, themoving image data is moving image data of medical images, but should notbe restricted to this.

As a sharpness improvement method, a reconfiguration-typesuper-resolution processing, learning-type super-resolution processing,or blurring removal processing, for example, may be used. Thereconfiguration-type super-resolution processing is processing to layerthe image data of multiple frames, based on the moving image data,thereby generating high quality still image data wherein the dynamicrange has been extended. Also, the learning-type super-resolutionprocessing is processing to perform super-resolution processing using adictionary that has been generated through learning, and generates highquality still image data. The blurring removal processing is processingto cancel blurring in an image and generate a sharp image, using blinddeconvolution, for example.

According to some embodiments of the present disclosure, searchinformation transmitted from a terminal device may be received by asearch information receiving unit. The still image data generated byprocessing predetermined moving image data with a predetermined program,corresponding to the search information, is transmitted to the terminaldevice by the image transmitting unit. For example, search informationincludes first information that identifies moving image data and secondinformation that identifies a processing program to generate still imagedata from the moving image data, and the still image data that has beengenerated by processing the moving image data identified by a firstinformation and by a processing program identified by the secondinformation, may be transmitted to the terminal device.

Thus, according to some embodiments of the present technology, the imageprocessing unit can automatically modify or add a processing program.Also, still image data generated by processing predetermined movingimage data corresponding to the search information transmitted from theterminal device with a predetermined processing program is transmittedto the terminal device. Therefore, it goes without saying that thedisplay terminal units can obtain high quality still image data by thenewest processing algorithm at a low cost, rather than performing imageprocessing by themselves. Further more, because medical images tend tocontain a large amount of information (e.g., stored in large files),processing of such images may be computationally intensive. In variousdisclosed embodiments, the terminal device can advantageously obtainhigh quality still image data without having to perform intensivecomputations locally. Also, the display terminal units can obtain stillimages with not only the newest version of the processing program, butwith an optional version of a processing program, and can be favorablyapplied to past observations such as medical images or the like. Invarious embodiments, a specific version of the processing program may beselected, which may or may not be the newest version. For example, if aspecific version was used to process past observations from a patient,it may be desirable to use the same version to process presentobservations of the patient to facilitate accurate comparison betweenthe past and present observations.

Note that according to some embodiments of the present technology, acache unit is further provided that holds the still image data generatedby the image processing unit, for example, and in the case that stillimage data corresponding to the search information from the terminaldevice is held in the cache unit, the image transmitting unit mayretrieve the still image data from the cache unit and transmit this tothe terminal device. By such a cache unit being provided, the stillimage data existing already in the cache unit does not have to begenerated by the image processing unit, and the still image datacorresponding to the search information can be efficiently transmittedto the terminal device.

For example, still image data generated by processing the moving imagedata stored in the storage unit by the newest version of the processingprogram in the image processing unit may conceivably be held in thecache unit. Also, for example, still image data generated by processingmoving image data stored in the storage unit by all of the processingprograms in the image processing unit may conceivably be held in thecache unit. Also, for example, still image data corresponding to thesearch information from the terminal device that has been transmitted tothe terminal device in the past by the image transmitting unit mayconceivably be held in the cache unit.

According to some further embodiments of the present disclosure, anapparatus is provided, comprising at least one processor programmed to:transmit, via at least one network, a request to another apparatus forstill image data generated from moving image data, the requestcomprising at least one criterion; and receive still image datagenerated from moving image data matching the at least onecriterion inthe request. According to yet some further embodiments of the presentdisclosure, a terminal device is provided that has a search informationtransmitting unit to transmit, to a server device, search informationincluding first information that identifies moving image data and secondinformation that identifies a processing program to generate still imagedata from the moving image data; and an image receiving unit to receivethe still image data generated by processing predetermined moving imagedata with a predetermined processing program, corresponding to thesearch information, the still image data having been transmitted fromthe server device.

According to some embodiments of the present technology, searchinformation may be transmitted from the search information transmittingunit to the server device. The search information includes firstinformation identifying moving image data and second informationidentifying a processing program to generate the still image data fromthe moving image data. Still image data generated by processingpredetermined moving image data corresponding to the search informationwhich is transmitted from the server device, with a predeterminedprocessing program, may be received by the image receiving unit.

Thus, according to some embodiments of the present technology, the firstinformation identifying moving image data and second informationidentifying a processing program to generate the still image data fromthe moving image data can be transmitted to the server device, and thestill image data generated by processing predetermined moving image datacorresponding to the search information from the server device, with apredetermined processing program, can be received. Accordingly, highquality still image data can be obtained by newest processing programsat a low cost, besides performing image processing by itself. Also,still images can be obtained, with not only the newest processingprogram, but with an optional processing program, and can be favorablyapplied to past observations such as medical images or the like.

Note that according to some embodiments of the present technology, auser interface unit may further be provided, to select whether toidentify the newest processing program in the second information orwhether to identify a processing program corresponding to the movingimage data identified by the first information. This user interface unitenables the user to readily identify a processing program.

Advantageous Effects of Invention

According to some embodiments of the present technology, a terminaldevice in a medical institution or the like can obtain high qualitystill image data by the newest processing program at a low cost, ratherthan performing image processing by itself. Also, according to thepresent technology, a terminal device in a medical institution or thelike can obtain still images with not only the newest processingprogram, but with an optional processing program, and can favorablyhandle chronological observations at a medical institution or the like.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 is a block diagram illustrating a configuration example of animage processing system in medical institutions.

FIG. 2 is a flowchart describing the flow of processing of the imageprocessing system.

FIG. 3 is a block diagram illustrating a configuration of an imageprocessing system according to a first embodiment.

FIG. 4 is a diagram illustrating an example of a GUI for a userinterface unit of a display terminal unit to display on a display.

FIG. 5 is a diagram illustrating examples of search informationtransmitted from the display terminal unit to a server device.

FIG. 6 is a diagram describing processing by the image processing unit.

FIG. 7 is a diagram illustrating examples of sharpness-improvingprocessing performed by the image processing unit.

FIG. 8 is a flowchart describing an example of processing procedures forstoring (saving) fundus moving image data in the image processingsystem.

FIG. 9 is a flowchart describing an example of user operating proceduresat a display terminal unit wherein search options cannot be set.

FIG. 10 is a flowchart describing an example of user operatingprocedures at a display terminal unit wherein search options can be set.

FIG. 11 is a flowchart describing an example of processing procedures ata display terminal unit wherein search options cannot be set.

FIG. 12 is a flowchart describing an example of processing procedures ata display terminal unit wherein search options can be set.

FIG. 13 is a flowchart describing an example of processing procedures ofsearch result (fundus still image data) transmission of a server device.

FIG. 14 is a flowchart describing another example of processingprocedures of search result (fundus still image data) transmission of aserver device.

FIG. 15 is a flowchart describing an example of search/displayprocessing procedures in the image processing system.

FIG. 16 is a block diagram illustrating a configuration example of animage processing system according to a second embodiment.

FIG. 17 is a flowchart describing an example of updating processing ofsaved content in a cache unit on a server device.

FIG. 18 is a flowchart describing another example of updating processingof saved content in a cache unit on a server device.

FIG. 19 is a flowchart describing yet another example of updatingprocessing of saved content in a cache unit on a server device.

FIG. 20 is a flowchart describing an example of processing procedures ofsearch result (fundus still image data) transmission of a server device.

FIG. 21 is a flowchart describing another example of processingprocedures of search result (fundus still image data) transmission of aserver device.

FIG. 22 is a flowchart describing an example of search/displayprocessing procedures in the image processing system.

DESCRIPTION OF EMBODIMENTS

Embodiments of the present disclosure (hereafter, “embodiments”) will bedescribed below. Note that description will be given in the followingorder.

1. First Embodiment

2. Second Embodiment

3. Modification

First, an example of an image processing system will be described. FIG.1 shows a configuration example of an image processing system providedto medical institutions. In FIG. 1, an image processing system 400-1,400-2, 400-3, and the like are provided to a medical institution 1,medical institution 2, and medical institution 3, respectively.

The image processing system 400 (400-1, 400-2, 400-3, and the like) willbe described. The image processing system 400 has a fundus camera 401,fundus moving image storage unit 402, image processing unit 403, fundusstill image storage unit 404, fundus image searching unit 405, anddisplay terminal unit 406.

The fundus camera 401 photographs a fundus image as a moving image. Thefundus moving image storage unit 402 temporarily stores the moving imagedata of the fundus image obtained by photographing with the funduscamera 401. The fundus moving image storage unit 402 is made up ofstorage such as an HDD or the like. The image processing unit 403generates fundus still image data from the moving image data stored inthe fundus moving image storage unit 402. In the image processing unit403, at least one of NR (noise reduction), sharpness improvement, and DR(dynamic range) improvement will be executed, and high quality fundusstill image data is generated.

The fundus still image storage unit 404 stores data of the fundus stillimage generated by the image processing unit 403. The fundus imagesearching unit 405 searches, from the fundus still image storage unit404, for fundus still image data corresponding to the search information(user ID, photograph date and time, etc.) that is transmitted from thedisplay terminal unit 406, reads out the fundus still image data fromthe fundus still image storage unit 404, and transmits this to thedisplay terminal unit 406. The display terminal unit 406 transmits thesearch information to the fundus image searching unit 405, receives thefundus still image data transmitted from the fundus image searching unit405, and displays a desired fundus still image.

The flowchart in FIG. 2 shows the processing flow of the imageprocessing system 400 (400-1, 400-2, 400-3, and the like). In step ST1the image processing system 400 starts the processing. Next, in step ST2the image processing system 400 photographs a fundus moving image withthe fundus camera 401. In step ST3, the image processing system 400 thensaves (stores) the fundus moving image data obtained by photographing inthe fundus moving image storage unit 402.

Next, in step ST4 the image processing system 400 performs processing atthe image processing unit 403 as to the fundus moving image data storedin the fundus moving image storage unit 402, thereby generating fundusstill image data. In step ST5, the image processing system 400 saves(stores) the fundus still image data generated by the image processingunit 403 in the fundus still image storage unit 404.

Next, in step ST6 the image processing system 400 specifies a searchtarget from the display terminal unit 406, i.e. transmits the searchinformation from the display terminal unit 406 to the fundus imagesearching unit 405. Also, in step ST6 the image processing system 400transmits the fundus still image data that the fundus image searchingunit 405 has searched for from the fundus still image storage unit 404to the display terminal unit 406, and displays the fundus still image onthe display terminal unit 406. In step ST7 the image processing system400 ends the processing.

In the image processing systems 400, fundus still image data isgenerated from the fundus moving image data by image processing, wherebyhigh quality fundus still image data can be obtained. In this case, theimage quality of the fundus still image depends on the performance ofthe image processing algorithm. In the case that a new image processingalgorithm is developed, updates to the hardware or software (processingprocess) has to be made in the image processing systems 400, resultingin high costs for the updates.

<1. First Embodiment>

“Configuration Example of Image Processing System”

FIG. 3 shows a configuration example of an image processing system 10according to a first embodiment of the present technology. This imageprocessing system 10 is made up of a server device 200 and terminaldevice being connected via a network 300. The fundus cameras 110-1,110-2, 110-3, and the like and display terminal units 120-1, 120-2,120-3, and the like each configure a terminal device. The fundus cameraand terminal display unit may be considered to exist, not onlyindependently as shown in the diagram, but also so as to be integratedtogether.

The fundus cameras 110-1, 110-2, 110-3, and the like photograph a fundusimage as a moving image and transmit the fundus moving image dataobtained by photographing to the server device 200 via the network 300.The display terminal units 120-1, 120-2, 120-3, and the like transmitthe search information to the server device 200 via the network 300.Also, the display terminal units 120-1, 120-2, 120-3, and the likereceive the fundus still image data corresponding to the searchinformation, which is transmitted from the server device 200 via thenetwork 300, and displays this on a display.

The search information will now be described. First information thatidentifies the fundus moving image data and second information thatidentifies the processing program are included in the searchinformation. Now, there may be cases wherein the examiner desires toperform past observations of images seen in the past used forexamination in the past. For example, the display terminal units 120-1,120-2, 120-3, and the like may be provided with a user interface unit toselect whether to identify the newest processing program with the secondinformation or whether to identify a processing program corresponding tothe fundus moving image data identified with the first information.

FIG. 4 shows an example of a GUI (Graphical User Interface) wherewiththe user interface unit of the display terminal units 120-1, 120-2,120-3, and the like displays on a display. Upon the user selecting“Process all with newest version” as the image processing version, thesecond information included in the search information identifies thenewest version of the processing program. On the other hand, upon theuser selecting “Process with version number saved for each movingimage”, the second information included in the search informationidentifies the version of the processing program that corresponds to thefundus moving image data identified with the first information.

FIG. 5 shows an example of search information transmitted from thedisplay terminal units 120-1, 120-2, 120-3, and the like to the serverdevice 200. FIG. 5(a) shows an example of personal ID (e.g., informationidentifying a patient or some other imaged subject and photograph dateperiod (e.g., April 1990 to current, etc.) information that is includedin the search information. In this example, the personal ID andphotograph date period make up the first information to identify thefundus moving image data. Also, in this example, there is no imageprocessing version number information, which makes up the secondinformation and identifies the newest processing program.

FIG. 5(b) shows an example of personal ID, photograph date and time, andimage processing version number information that is included in thesearch information. In this example, the personal ID and photograph dateand time makes up the first information to identify the fundus movingimage data. Also, in this example, the image processing version numbermakes up the second information to identify the processing program.

The server device 200 has a fundus moving image storage unit 201, fundusimage searching unit 202, and image processing unit 203. The fundusmoving image storage unit 201 stores the fundus moving image datatransmitted from the fundus cameras 110-1, 110-2, 110-3, and the like,via the network 300. The fundus moving image data stored thus in thefundus moving image storage unit 201 has information such as personalID, photograph date and time, etc. appended thereto for searching. Thefundus image searching unit 202 searches for and reads out the fundusmoving image data corresponding to the search information from thefundus moving image storage unit 201, and transmits this to the imageprocessing unit 203.

The image processing unit 203 can automatically update or add aprocessing program. That is to say, in the case that a new imageprocessing algorithm is developed, updating or adding of the processingprogram is performed. According to this embodiment, adding of theprocessing program is performed. That is to say, while the old versionof the processing program remains, a new version of the processingprogram is added.

The image processing unit 203 processes the fundus moving image datatransmitted from the fundus image searching unit 202 with the processingprogram identified by the search information to generate the fundusstill image data. The image processing unit 203 then transmits thegenerated fundus still image data to the display terminal unit 120 whichis the transmission source of the search information, via the network300.

Now, processing by the image processing unit 203 will be furtherdescribed. As shown in FIG. 6, the image processing unit 203 executesone or more of NR (noise reduction), sharpness improvement, and DR(dynamic range) improvement, and from the data Vin of the fundus movingimage, generates high quality data Vout of the fundus still image. Assharpness improvement processing, the image processing unit 203 usesreconfiguration-type super-resolution processing, learning-typesuper-resolution processing, or blurring removal processing, forexample, as shown in FIGS. 7 (a), (b), and (c).

The reconfiguration-type super-resolution processing is processing tolayer the image data of multiple frames, based on the moving image data,thereby generating high quality still image data wherein the dynamicrange has been extended. Also, the learning-type super-resolutionprocessing is processing to perform super-resolution processing using adictionary that has been generated through learning, and generates highquality still image data. While detailed descriptions will be omitted,the reconfiguration-type super-resolution processing and learning-typesuper-resolution processing are described in Japanese Patent ApplicationNo. 2010-258556 by the present applicant.

The blurring removal processing is processing to cancel blurring in animage and generate a sharp image, using blind deconvolution, forexample. The blurring removal processing will be further described.

Let us say that a Point Spread Function (PSF) that expresses theinput/output properties of an optical system is represented by h(x, y),the observed image by g(x, y), the true image by f(x, y), and Fouriertransforms by H(u, v), G(u, v), and F(u, v), respectively. At this time,the following relational expressions hold between these expressions(noise is omitted for simplicity).g(x, y)=h(x,y)*f(x, y)G(u, v)=H(u,v)F(u, v)G(u, v)=z[g(x, y)]H(u,v)=z[h(x, y)]F(u, v)=z[f(x, y)]z [ ]: Fourier Transform

In the case the optical system has a blurring property, blurring occursin the observed image g(x, y). At this time, canceling the blurring ofthe observed image and obtaining a sharp image (true image: f(x, y))indicates that f(x, y) is obtained from g(x, y) (F(u, v) is obtainedfrom G(u, v)). This processing is called deconvolution. If h(x, y) (orH(u, v)) is a known value, deconvolution can be performed, but if not aknown value, this value has to be estimated.

A method for obtaining an image without blurring f(x, y) from a blurredimage g(x, y) that has been photographed in the case that h(x, y) (orH(u, v)) is not a known value is blind deconvolution. This is a methodto simultaneously estimate f(x, y) and h(x, y) based on some sort of apriori information relating to the non-blurring image f(x, y) and pointspread function h(x, y).

Blind deconvolution is used for blurring removal processing, forexample. The following is an example of a document relating to aspecific method of blind deconvolution, for example.

G. R. Ayers and J. C. Dainty: “Iterative blind deconvolution method andits applications,” Optics Letters, Vol. 13, pp. 547-549 (1988)

The operations of the image processing system 10 shown in FIG. 3 will bedescribed. First, the storage (saving) processing of fundus moving imagedata in the image processing system 10 will be described. The flowchartin FIG. 8 shows an example of the processing procedures thereof. In stepST11 the image processing system 10 starts the processing. In step ST12,the fundus camera 110 (110-1, 110-2, 110-3, and the like) photographsthe fundus image as a moving image.

Next, in step ST13, the fundus camera 110 transmits the fundus movingimage data obtained by photographing to the server device 200 via thenetwork 300. Also, in step ST13, the server device 200 stores (saves)the fundus moving image data transmitted from the fundus camera 110 inthe fundus moving image storage unit 201. In step ST14 the imageprocessing system 10 ends the processing.

Next, operations for fundus still image observation by a user of thedisplay terminal unit 120 (120-1, 120-2, 120-3, and the like) will bedescribed. The flowchart in FIG. 9 shows an example of operatingprocedures by a user of a display terminal unit 120 wherein processingprogram version selection(hereafter called “search option setting”),such as described with reference to FIG. 4 above, cannot be made.

In step ST21 the user starts the operations for fundus still imageobservation. In step ST22, the user specifies a search target. In thiscase, the user specifies the search target by specifying the period ofphotograph dates, photograph date and time, and so forth, for example.Next, in step ST23, upon a receipt notification of search results(fundus still image data) being displayed on the display, the userdisplays and observes the fundus still image on the display. In stepST24, the user then ends the operations for fundus still imageobservation.

The flowchart in FIG. 10 shows an example of user operating proceduresof the display terminal 120 wherein search options can be set. In stepST31, the user starts the operation for observing fundus still images.In step ST32 the user determines whether or not to set the searchoptions. When determination has been made to set the search option, instep ST33 the user sets the search option. For example with the GUIshown in FIG. 4 described above, the user selects “Process all withnewest version” or “Process with version number saved for each movingimage”.

Following the operation in step ST33 the user transitions to theoperation in step ST34. Note that upon determining not to set the searchoption in step ST32, the user immediately transitions to the option instep ST34. In step ST34 the user specifies the search target. In thiscase, the user specifies a search target by specifying a period ofphotograph dates, the photograph date and time, or the like, forexample. Next, in step ST35, upon a receipt notification of the searchresult (fundus still image data) being displayed on the display, theuser displays and observes the fundus still image on the display. Instep ST36, the user ends the operation for fundus still imageobservation.

Next, processing procedures for transmission of the search informationof the display terminal unit 120 and reception of the search result(fundus still image data) will be described. The flowchart in FIG. 11shows an example of processing procedures of a display terminal unit 120wherein search options cannot be set. In step ST41, the display terminalunit 120 starts the processing. In step ST42 the display terminal unit120 transmits the search information (search request) to the serverdevice 200 via the network 300. The search information in this case isin a format such as shown in FIG. 5(a) described above, for example.

Note that cases may be considered wherein the search information is in aformat such as shown in FIG. 5(b) described above, for example. Forexample, the display terminal unit 120 saves the version number of theimage processing (processing program) corresponding to the dates andtimes received in the past as search results. For an image from a dateand time that has been searched in the past, the display terminal unit120 specifies a version number for image processing that has been saved,and for an image from a date and time that has not been searched in thepast, a version number indicating “the newest version” is specified andsearch information is transmitted.

Next, in step ST43, upon receiving the search results (fundus stillimage data) from the server device 200 via the network 300, the displayterminal unit 120 notifies the user that the search results have beenreceived. Note that following this notification, the display terminalunit 120 displays the fundus still image on a display, automatically orbased on operation by the user. Following the processing in step ST43,the display terminal unit 120, in step ST44 the processing is ended.

The flowchart in FIG. 12 shows an example of processing procedures of adisplay terminal unit 120 wherein search options can be set. In stepST51 the display terminal unit 120 starts the processing. In step ST52the display terminal unit 120 determines which of “Process all withnewest version” or “Process with version number saved for each movingimage” has been set.

When “Process all with newest version” is set, in step ST53 the displayterminal unit 120 transmits search information in a format such as thatshown in FIG. 5(b), for example, to the server device 200 via thenetwork 300. In this case, the newest version number that can beprocessed with the server device 200 is written into “image processingversion number” in the search information. Note that in this case, onlythe newest version number is written into “image processing versionnumber”, whereby search information in a format such as that shown inFIG. 5(a), for example, may also be transmitted.

On the other hand, when “Process with version number saved for eachmoving image” has been set, in step ST54 the display terminal unit 120transmits the search information in a format such as that shown in FIG.5(b), for example, to the server device 200 via the network 300. In thiscase, if there is a version number saved as to the photograph date andtime, the number thereof is written in the “image processing versionnumber” in the search information, and if none, the newest versionnumber that can be processed with the server device 200 is writtentherein.

Following the processing in step ST53 or step ST54, the display terminalunit 120 transitions to the processing in step ST55. In step ST55, uponreceiving the search result (fundus still image data) from the serverdevice 200 via the network 300, the display terminal unit 120 saves the“image processing version number” of the received fundus still imagedata.

Next, in step ST56 the display terminal unit 120 notifies the user ofthe receipt of the search results. Note that following thisnotification, the display terminal unit 120 displays the fundus stillimage on a display, automatically or based on user operations. Followingthe processing in step ST56, instep ST57 the display terminal unit 120ends the processing.

Note that the processing procedures shown in the flowchart in FIG. 12are configured so that the display terminal unit 120 saves the imageprocessing version number corresponding to the photograph date and time.However, the server device 200 may save a combination of the photographdate and time and the image processing version numbers, corresponding toeach display terminal unit 120.

Next, processing procedures of the search result (fundus still imagedata) transmission of the server device 200 will be described. Theflowchart in FIG. 13 shows an example of processing procedures of theserver device 200 in the case that search information is supplied forthe display terminal unit 120 in a format such as shown in FIG. 5(a).

In step ST61 the server device 200 starts the processing. In step ST62,the server device 200 processes the fundus moving image data of aphotograph date period, of the fundus moving image data stored in thefundus moving image storage unit 201, with the newest version of theprocessing program in the image processing unit 203, to generate fundusstill image data.

Also, in step ST62, the server device 200 transmits the generated fundusstill image data as search results to the display terminal unit 120 viathe network 300. In this event, the image processing version number isalso appended to the still image data. Following the processing in stepST62, in step ST63 the server device 200 ends the processing.

The flowchart in FIG. 14 shows an example or processing procedures ofthe server device 200 in the case that search information is suppliedfrom the display terminal unit 120 in a format such as shown in FIG.5(b). In step ST71 the server device 200 starts the processing. In stepST72 the server device 200 processes the fundus moving image data of aphotograph date and time, of the moving image data stored in the fundusmoving image storage unit 201, with the specified version of theprocessing program, by the image processing unit 203, to generate fundusstill image data.

Also, in step ST72 the server device 200 transmits the generated stillimage data as search results to the display terminal unit 120 via thenetwork 300. In this event, the image processing version number is alsoappended to the still image data. Note that in the case that a specifiedversion of a processing program is not installed in the image processingunit 203, and processing thereby cannot be performed, processing isperformed with the processing program having the nearest version to thespecified version. Following the processing in step ST72, in step ST73the server device 200 ends the processing.

In the event of transmitting the fundus still image data that has beenprocessed and obtained with a version different from the versionspecified as described above to the display terminal unit 120 as searchresults, in order to clarify the fact thereof, a warning message may beappended.

Next, search/display processing in the image processing system 10 willbe described. The flowchart in FIG. 15 shows an example of theprocessing procedures thereof. In step ST81 the image processing system10 starts the processing. In step ST82 the search target is specified bythe display terminal unit 120. That is to say, the search information(see FIGS. 5(a) and (b)) is transmitted to the server device 200 via thenetwork 300.

Next, in step ST83 the fundus image searching unit 202 of the serverdevice 200 searches for the data of the fundus moving imagecorresponding to the search information from the fundus moving imagestorage unit 201, and supplies this to the image processing unit 203. Instep ST84 the image processing unit 203 of the server device 200processes the fundus moving image data with a processing program of aversion corresponding to the search information, to generate fundusstill image data. Also, in step ST84 the server device 200 transfers thefundus still image data generated by the image processing unit 203 assearch results to the display terminal unit 120 which is thetransmission source of the search information, via the network 300.

Next, in step ST85, the display terminal unit 120 displays the fundusstill image on the display, based on the fundus still image datatransferred from the server device 200. Following the processing in stepST85, the image processing system 10 ends the processing in step ST86.

As described above, in the image processing system 10 shown in FIG. 3,the image processing unit 203 of the server device 200 can automaticallymodify or add a processing program. Search information is transmittedfrom the display terminal unit 120 serving as a terminal device to theserver device 200, and fundus moving image data corresponding to thesearch information is searched for in the fundus moving image storageunit 201 and supplied to the image processing unit 203. In the imageprocessing unit 203, the fundus moving image data is processed by aprocessing program of a version corresponding to the search information,and fundus still image data is generated and transmitted to the displayterminal unit 120.

The display terminal units 120 do not perform image processing bythemselves, but can obtain high quality still image data by the newestprocessing algorithm at a low cost. Also, the display terminal units 120can obtain still images with not only the newest version of theprocessing program, but with an optional version of a processingprogram, and can be favorably applied to past observations such asmedical images or the like.

<2. Second Embodiment>

“Configuration Example of Image Processing System”

FIG. 16 shows a configuration example of an image processing system 10Aaccording to a second embodiment of the present technology. In FIG. 16,the portions corresponding to FIG. 3 have the same reference numeralsappended thereto, and detailed descriptions thereof will be omitted asappropriate. The image processing system 10A is made up with a serverdevice 200A and terminal device being connected via the network 300. Thefundus cameras 110-1, 110-2, 110-3, and the like and the displayterminal units 120-1, 120-2, 120-3, and the like each configure aterminal device. The fundus camera and terminal display unit may beconsidered to exist, not only independently as shown in the diagram, butalso so as to be integrated together.

The fundus cameras 110-1, 110-2, 110-3, and the like photograph a fundusimage as a moving image and transmit the fundus moving image dataobtained by photographing to the server device 200A via the network 300.The display terminal units 120-1, 120-2, 120-3, and the like transmitthe search information (see FIGS. 5(a) and (b)) to the server device200A via the network 300. Also, the display terminal units 120-1, 120-2,120-3, and the like receive the fundus still image data corresponding tothe search information, which is transmitted from the server device 200Avia the network 300, and displays this on a display.

The server device 200A has a fundus moving storage unit 201, fundusimage searching unit 202, image processing unit 203, and cache unit 204.The fundus moving storage unit 201 stores the fundus moving image datathat is transmitted from the fundus cameras 110-1, 110-2, 110-3, and thelike via the network 300. Information such as a personal ID, photographdate and time and so forth are appended to the fundus moving image datastored in the fundus moving image storage unit 201, for searching.

The image processing unit 203 can automatically update or add aprocessing program. That is to say, in the case that a new imageprocessing algorithm is developed, updating or adding of the processingprogram is performed. According to this embodiment, adding of theprocessing program is performed. That is to say, while the old versionof the processing program remains, a new version of the processingprogram is added.

The image processing unit 203 processes the fundus moving image datatransmitted from the fundus image searching unit 202 with the processingprogram identified by the search information, to generate the fundusstill image data. The cache unit 204 holds the fundus still image datagenerated by the image processing unit 203. When the fundus still imagedata corresponding to the search information is being held in the cacheunit 204, the server device 200A retrieves the fundus still image datafrom the cache unit 204 and transmits this to the display terminal unitwhich is the transmission source of the search information via thenetwork 300.

When the fundus still image data corresponding to the search informationis not held in the cache unit 204, the fundus image searching unit 202searches and reads out the fundus moving image data corresponding to thesearch information from the fundus moving image storage unit 201, andtransmits this to the image processing unit 203. On the other hand, whenthe fundus still image data corresponding to the search information isnot held in the cache unit 204, the server device 200A transmits thefundus still image data corresponding to the search informationgenerated by the image processing unit 203 to the display terminal unitwhich is the transmission source of the search information, via thenetwork 300.

For example, fundus still image data, which is fundus moving image datastored in the fundus moving image storage unit 201 that has beenprocessed and generated by the newest version of the processing programin the image processing unit 203, is held in the cache unit 204. Theflowchart in FIG. 17 shows an example of updating processing of the heldcontent in the cache unit 204 in the server device 200A.

In step ST91 the server device 200A starts the processing. In step ST92,the server device 200A determines whether or not a new version of theprocessing program (new algorithm) has been installed in the imageprocessing unit 203. When a new version of the processing program hasbeen installed, in step ST93 the server device 200A deletes all of thefundus still image data generated by the past processing programs heldin the cache unit 204.

In step ST94, the server device 200A processes all of the fundus movingimage data existing in the fundus moving image storage unit 201 with thenew version of the processing program in the image processing unit 203,generates fundus still image data, and saves this in the cache unit 204.Following the processing in step ST94, the server device 200A returns tothe processing in step ST92.

On the other hand, when a new version of the processing program is notinstalled in the image processing unit 203 in step ST92, in step ST95the server device 200A determines whether or not fundus moving imagedata has been added to the fundus moving image storage unit 201. Whenfundus moving image data has not been added, the server device 200Aimmediately returns to the processing in step ST92.

When fundus moving image data has been added in step ST95, the serverdevice 200A transitions to the processing in step ST96. In step ST96 theserver device 200A processes all of the added fundus moving image datawith the newest version of the processing program in the imageprocessing unit 203 to generate fundus still image data, and saves thisin the cache unit 204. Following the processing in step ST96, the serverdevice 200A returns to the processing in step ST92.

Also, for example, fundus still image data, which is fundus moving imagedata stored in the fundus moving image storage unit 201 that has beenprocessed and generated by all of the processing programs in the imageprocessing unit 203, is held in the cache unit 204. The flowchart inFIG. 18 shows an example of updating processing of the held content inthe cache unit 204 in the server device 200A.

In step ST101, the server device 200A starts the processing. In stepST102, the server device 200A determines whether or not a new version ofthe processing program (new algorithm) has been installed in the imageprocessing unit 203. When a new version of the processing program hasbeen installed, the server device 200A transitions to the processing instep ST103.

In step ST103, the server device 200A processes all of the fundus movingimage data existing in the fundus moving image storage unit 201 with thenew version of the processing program in the image processing unit 203,generates fundus still image data, and saves this in the cache unit 204.Following the processing in step ST103, the server device 200A returnsto the processing in step ST102.

On the other hand, when a new version of the processing program is notinstalled in the image processing unit 203 in step ST102, in step ST104the server device 200A determines whether or not fundus moving imagedata has been added to the fundus moving image storage unit 201. Whenfundus moving image data has not been added, the server device 200Aimmediately returns to the processing in step ST102.

When fundus moving image data has been added in step ST104, the serverdevice 200A transitions to the processing in step ST105. In step ST105the server device 200A processes all of the added fundus moving imagedata with all of the processing programs in the image processing unit203 to generate fundus still image data, and saves this in the cacheunit 204. Following the processing in step ST105, the server device 200Areturns to the processing in step ST102.

Further, for example, the fundus still image data that has beengenerated in the past by the image processing unit 203 and transferredto the cache unit 204, then transmitted to the display terminal unit atthe transmission source of the search information via the network 300,is held in the cache unit 204. The flowchart in FIG. 19 shows an exampleof the updating processing of the holding content in the cache unit 204in the server device 200A.

In step ST111 the server device 200A starts the processing. In stepST112, the server device 200A determines whether or not there is anyfundus still image data that has been transferred from the imageprocessing unit 203 to the cache unit 204. When there is no fundus stillimage data transferred from the image processing unit 203 to the cacheunit 204, the server device 200A immediately returns to the processingin step ST112.

On the other hand, when there is fundus still image data that has beentransferred to the cache unit 204 from the image processing unit 203,the server device 200A transitions to the processing in step ST113. Instep ST113 the server device 200A saves the transferred fundus stillimage data to the cache unit 204. Following the processing in stepST113, the server device 200A returns to the processing in step ST112.

Note that in the event of following the procedures of the updatingprocessing shown in the flowchart in FIG. 19, at the point in time thatthe data amount within the cache unit 203 has exceeded a fixed valuedetermined beforehand, the fundus still image data having the earliestpoint-in-time of being saved to the cache unit 204 may be deleted.

The operations of the image processing system 10A shown in FIG. 16 willbe described. The processing for storing (saving) the fundus movingimage data in the image processing system 10A is similar to the storage(saving)processing in the image processing system 10 shown in FIG. 3(see FIG. 8). Also, the user operations for fundus still imageobservation of the display terminal unit 120 in the image processingsystem 10A is similar to the user operations of the image processingsystem 10 shown in FIG. 3 (see FIG. 9 and FIG. 10). Further, theprocessing procedures of the search information transmission and searchresult (fundus still image data) reception of the display terminal unit120 in the image processing system 10A are similar to the processingprocedures in the image processing system 10 shown in FIG. 3 (see FIGS.11 and 12).

The processing procedures of search result (fundus still image data)transmission of the server device 200A will be described. The flowchartin FIG. 20 shows an example of processing procedures of the serverdevice 200A in the case that search information is supplied from thedisplay terminal unit 120 in a format such as shown in FIG. 5(a).

In step ST121 the server device 200A starts the processing. In stepST122, when there is fundus still image data in the cache unit 204corresponding to the search information, the server device 200A sets thefundus still image data thereof as the search results. Also, in stepST122, when there is no fundus still image data in the cache unit 204corresponding to the search information, the server device 200A sets thefollowing as the search results. That is to say, of the fundus movingimage data stored in the fundus moving image storage unit 201, thefundus still image data generated by processing the fundus image datafrom a period of photograph dates with the newest version of theprocessing program in the image processing unit 203, is set as thesearch results.

In step ST122, the server device 200A transmits the fundus still imagedata serving as the search results to the display terminal unit 120which is the transmission source of the search information, via thenetwork 300. In this event, the version number of the image processingis also appended to the still image data. Following the processing instep ST122, in step ST123 the server device 200A ends the processing.

The flowchart in FIG. 21 shows an example of the processing proceduresof the server device 200A in the case that search information issupplied from the display terminal unit 120 in a format such as shown inFIG. 5(b). In step ST131, the server device 200A starts the processing.In step ST132, when there is fundus still image data in the cache unit204 corresponding to the search information, the server device 200A setsthe fundus still image data thereof as the search results.

Also, in step ST132, when there is no fundus still image data in thecache unit 204 corresponding to the search information, the serverdevice 200A sets the following as the search results. That is to say, ofthe fundus moving image data stored in the fundus moving image storageunit 201, the server device 200A processes the fundus moving image dataof a photograph date and time with the version of the processing programspecified by the image processing unit 203, and sets the generatedfundus still image data as the search results.

Note that in the case that no processing program of a version specifiedby the search information has been installed, the server device 200Asets the following as the search results. That is to say, of the fundusstill images that can be generated by the image processing unit 203 orthe fundus still images in the cache unit 204, the fundus still imagedata generated by the processing program of the version nearest thespecified version is set by the server device 200A as the searchresults.

Also, in step ST132, the server device 200A transmits the fundus stillimage data serving as the search results to the display terminal unit100 which is the transmission source of the search information, via thenetwork 300. In this event, the image processing version number is alsoappended to the still image data. Following the processing in stepST132, in step ST133 the server device 200A ends the processing.

Next, the search/display processing in the image processing system 10Awill be described. The flowchart in FIG. 22 shows an example of theprocessing procedures thereof. In step ST141 the image processing system10A starts the processing. In step ST142 the search target is specifiedfrom the display terminal unit 120. That is to say, the display terminalunit 120 transmits the search information (see FIGS. 5(a) and (b)) tothe server device 200A via the network 300.

Next, in step ST 143 the server device 200A determines whether or notthere is any fundus still image data in the cache unit 204 correspondingto the search information. When there is fundus still image data in thecache unit 204 corresponding to the search information, the serverdevice 200A sets the fundus still image data thereof as the searchresults, and transitions to the processing in step ST147.

When there is no fundus still image data in the cache unit 204corresponding to the search information, the server device 200Atransitions to the processing instep ST144. In step ST144, the cacheunit 204 of the server device 200A transfers the search information tothe fundus image searching unit 202. In step ST 145, the fundus imagesearching unit 202 of the server device 200A searches for the fundusmoving image data corresponding to the search information from thefundus moving image storage unit 201, and supplies this to the imageprocessing unit 203.

In step ST146, the image processing unit 203 of the server device 200Aprocesses the fundus moving image data with the processing program of aversion corresponding to the search information to generate fundus stillimage data, and transfers this, as the search results, to the cache unit204. Following the processing in step ST146, the server device 200Atransitions to the processing in step ST147.

In step ST147, the cache unit 204 of the server device 200A transfersthe fundus still image data serving as the search results to the displayterminal unit 120 which is the transmission source of the searchinformation, via the network300. In step ST148, the display terminalunit 120 displays the fundus still image on a display, based on thefundus still image data transferred from the server device 200A.Following the processing in step ST148, in step ST149 the imageprocessing system 10A ends the processing.

As described above, in the image processing system 10A shown in FIG. 16,the image processing unit 203 of the server device 200A canautomatically modify or add a processing program. Search information istransmitted from the display terminal unit 120 serving as a terminaldevice to the server device 200A, and fundus still image datacorresponding to the search information is transmitted from the serverdevice 200A to the display terminal unit 120. The display terminal units120 do not perform image processing by themselves, but can obtain highquality still image data by the newest processing algorithm at a lowcost. Also, the display terminal units 120 can obtain still images withnot only the newest version of the processing program, but with anoptional version of a processing program, and can be favorably appliedto past observations such as medical images or the like.

Also, in the image processing system 10A shown in FIG. 16, a cache unit204 to hold the fundus still image data is provided to the server device200A. In the case there is fundus still image data in the cache unit 204corresponding to the search information, the fundus still image data isretrieved and transmitted to the display terminal unit 120. Accordingly,the fundus still image data existing already in the cache unit 204 doesnot have to be generated with the image processing unit 203, and thestill image data corresponding to the search information can beefficiently transmitted to the display terminal unit 120.

<3. Modification>

Note that according to the above-described embodiments, examples havebeen giving of handling a fundus image as an image. However, it goeswithout saying that the present technology can similarly be applied toother medical images, and further, images other than medical images,such as monitoring images, for example. The above-described embodimentsof the present invention can be implemented in any of numerous ways. Forexample, the embodiments may be implemented using hardware, software ora combination thereof. When implemented in software, the software codecan be executed on any suitable processor or collection of processors,whether provided in a single computer or distributed among multiplecomputers. It should be appreciated that any component or collection ofcomponents that perform the functions described above can be genericallyconsidered as one or more controllers that control the above-discussedfunctions. The one or more controllers can be implemented in numerousways, such as with dedicated hardware, or with general purpose hardware(e.g., one or more processors) that is programmed using microcode orsoftware to perform the functions recited above. In this respect, itshould be appreciated that one implementation of embodiments of thepresent invention comprises at least one computer-readable storagemedium (i.e., a tangible, non-transitory computer-readable medium, suchas a computer memory, a floppy disk, a compact disk, a magnetic tape, orother tangible, non-transitory computer-readable medium) encoded with acomputer program (i.e., a plurality of instructions), which, whenexecuted on one or more processors, performs above-discussed functionsof embodiments of the present invention. The computer-readable storagemedium can be transportable such that the program stored thereon can beloaded onto any computer resource to implement aspects of the presentinvention discussed herein. In addition, it should be appreciated thatthe reference to a computer program which, when executed, performs anyof the above-discussed functions, is not limited to an applicationprogram running on a host computer. Rather, the term “computer program”is used herein in a generic sense to reference any type of computer code(e.g., software or microcode) that can be employed to program one ormore processors to implement above-discussed aspects of the presentinvention.

Also, various embodiments of the present technology can assumeconfigurations such as described below.

1. An apparatus comprising at least one processor programmed to:

transmit, via at least one network, a request to another apparatus forstill image data generated from moving image data, the requestcomprising at least one criterion; and

receive still image data generated from moving image data matching theat least one criterion in the request.

2. The apparatus of configuration 1, wherein the at least one processoris further programmed to:

include in the request information identifying at least one imageprocessing technique for use in generating the moving image data fromthe still image data.

3. The apparatus of configuration 2, wherein the information identifyingthe at least one image processing technique comprises an identifier fora version of an image processing program for use in generating the stillimage data from the moving image data.

4. The apparatus of configuration 3, further comprising at least oneinput device, wherein the at least one processor is further programmedto:

receive user input via the at least one input device; and

select the version of the image processing program based at least inpart on the user input.

5. The apparatus of configuration 2, wherein the information identifyingthe at least one image processing technique comprises an indication thata newest image processing technique is to be used in generating thestill image data from the moving image data.

6. The apparatus of configuration 5, wherein the information identifyingthe at least one image processing technique comprises an indication thata newest version of an image processing program be used in generatingthe still image data from the moving image data.

7. The apparatus of configuration 2, wherein the at least one imageprocessing technique comprises an image processing technique selectedfrom a group consisting of: reconfiguration-type super-resolutionprocessing, learning-type super-resolution processing, and blurringremoval processing.

8. The apparatus of configuration 1, further comprising at least oneimaging device configured to capture a moving image and thereby generatethe moving image data, wherein the at least one processor is furtherprogrammed to:

transmit the moving image data to the other apparatus.

9. The apparatus of configuration 8, wherein the at least one imagingdevice comprises at least one medical imaging device configured tocapture a moving image from an observation target.

10. The apparatus of configuration 9, wherein the at least one medicalimaging device comprises a funduscope configured to capture a movingimage from the fundus of an eye of a patient.

11. The apparatus of configuration 1, wherein the at least one processoris further programmed to:

upon receiving the still image data, notify a user that the still imagedata is available.

12. The apparatus of configuration 1, further comprising at least onedisplay device, wherein the at least one processor is further programmedto:

cause the at least one display device to display a still image to theuser based on the still image data.

13. The apparatus of configuration 1, further comprising at least oneinput device, wherein the at least one processor is further programmedto:

receive user input via the at least one input device; and

determine the at least one criterion based at least in part on the userinput.

14. The apparatus of configuration 13, wherein the at least oneprocessor is further programmed to:

receive time information from the user via the at least one inputdevice; and

determine the at least one criterion based at least in part on the timeinformation.

15. The apparatus of configuration 13, wherein the at least oneprocessor is further programmed to:

receive personal identification information from the user via the atleast one input device; and

determine the at least one criterion based at least in part on thepersonal identification information.

16. The apparatus of configuration 15, wherein the moving image datacomprises medical moving image data, and wherein the personalidentification information comprises information identifying a patientwho is a subject of the medical moving image data.

17. An apparatus comprising:

means for transmitting, via at least one network, a request to anotherapparatus for still image data generated from moving image data, therequest comprising at least one criterion; and

means for receiving still image data generated from moving image datamatching the at least one criterion in the request.

18. The apparatus of configuration 17, further comprising means forincluding in the request information identifying at least one imageprocessing technique for use in generating the moving image data fromthe still image data.

19. The apparatus of configuration 18, wherein the informationidentifying the at least one image processing technique comprises anidentifier for a version of an image processing program for use ingenerating the still image data from the moving image data.

20. The apparatus of configuration 19, further comprising:

means for receiving user input; and

means for selecting the version of the image processing program based atleast in part on the user input.

21. The apparatus of configuration 18, wherein the informationidentifying the at least one image processing technique comprises anindication that a newest image processing technique is to be used ingenerating the still image data from the moving image data.

22. The apparatus of configuration 21, wherein the informationidentifying the at least one image processing technique comprises anindication that a newest version of an image processing program is to beused in generating the still image data from the moving image data.

23. The apparatus of configuration 18, wherein the at least one imageprocessing technique comprises an image processing technique selectedfrom a group consisting of: reconfiguration-type super-resolutionprocessing, learning-type super-resolution processing, and blurringremoval processing.

24. The apparatus of configuration 17, further comprising:

means for capturing a moving image and thereby generating the movingimage data; and

means for transmitting the moving image data to the other apparatus.

25. The apparatus of configuration 24, wherein the means for capturingthe moving image comprises means for capturing a medical moving imagefrom an observation target.

26. The apparatus of configuration 25, wherein the means for capturing amedical moving image comprises means for capturing a moving image fromthe fundus of an eye of a patient.

27. The apparatus of configuration 17, further comprising means for,upon receiving the still image data, notifying a user that the stillimage data is available.

28. The apparatus of configuration 17, further comprising means fordisplaying a still image to the user based on the still image data.

29. The apparatus of configuration 17, further comprising:

means for receiving user input; and

means for determining the at least one criterion based at least in parton the user input.

30. The apparatus of configuration 29, wherein the means for receivinguser input is configured to receive time information from the user, andwherein the means for determining the at least one criterion isconfigured to determine the at least one criterion based at least inpart on the time information.

31. The apparatus of configuration 29, wherein the means for receivinguser input is configured to receive personal identification informationfrom the user, and wherein the means for determining the at least onecriterion is configured to determine the at least one criterion based atleast in part on the personal identification information.

32. The apparatus of configuration 31, wherein the moving image datacomprises medical moving image data, and wherein the personalidentification information comprises information identifying a patientwho is a subject of the medical moving image data.

33. A method comprising acts of:

transmitting, from a first apparatus to a second apparatus, via at leastone network, a request for still image data generated from moving imagedata, the request comprising at least one criterion; and

receiving still image data generated from moving image data matching theat least one criterion in the request.

34. The method of configuration 33, further comprising:

including in the request information identifying at least one imageprocessing technique for use in generating the moving image data fromthe still image data.

35. The method of configuration 34, wherein the information identifyingthe at least one image processing technique comprises an identifier fora version of an image processing program for use in generating the stillimage data from the moving image data.

36. The method of configuration 35, further comprising:

receiving user input via at least one input device; and

selecting the version of the image processing program based at least inpart on the user input.

37. The method of configuration 34, wherein the information identifyingthe at least one image processing technique comprises an indication thata newest image processing technique is to be used in generating thestill image data from the moving image data.

38. The method of configuration 37, wherein the information identifyingthe at least one image processing technique comprises an indication thata newest version of an image processing program is to be used ingenerating the still image data from the moving image data.

39. The method of configuration 34, wherein the at least one imageprocessing technique comprises an image processing technique selectedfrom a group consisting of: reconfiguration-type super-resolutionprocessing, learning-type super-resolution processing, and blurringremoval processing.

40. The method of configuration 33, further comprising:

capturing a moving image and thereby generating the moving image data;

transmitting the moving image data to the second apparatus.

41. The method of configuration 40, wherein capturing the moving imagecomprises capturing a medical moving image from an observation target.

42. The method of configuration 41, wherein capturing the medical movingimage comprises using a funduscope to capture a moving image from thefundus of an eye of a patient.

43. The method of configuration 33, further comprising:

upon receiving the still image data, notifying a user that the stillimage data is available.

44. The method of configuration 33, further comprising:

displaying a still image to the user based on the still image data.

45. The method of configuration 33, further comprising:

receiving user input via at least one input device; and

determining the at least one criterion based at least in part on theuser input.

46. The method of configuration 45, wherein the user input comprisestime information, and wherein determining the at least one criterioncomprises determining the at least one criterion based at least in parton the time information.

47. The method of configuration 45, wherein the user input comprisespersonal identification information, and wherein determining the atleast one criterion comprises determining the at least one criterionbased at least in part on the personal identification information.

48. The method of configuration 47, wherein the moving image datacomprises medical moving image data, and wherein the personalidentification information comprises information identifying a patientwho is a subject of the medical moving image data.

49. At least one computer-readable storage medium encoded withinstructions that, when executed by at least one processor, perform amethod comprising acts of:

transmitting, from a first apparatus to a second apparatus, via at leastone network, a request for still image data generated from moving imagedata, the request comprising at least one criterion; and

receiving still image data generated from moving image data matching theat least one criterion in the request.

50. The at least one computer-readable storage medium of configuration49, wherein the method further comprises:

including in the request information identifying at least one imageprocessing technique for use in generating the moving image data fromthe still image data.

51. The at least one computer-readable storage medium of configuration50, wherein the information identifying the at least one imageprocessing technique comprises an identifier for a version of an imageprocessing program for use in generating the still image data from themoving image data.

52. The at least one computer-readable storage medium of configuration51, wherein the method further comprises:

receiving user input via at least one input device; and

selecting the version of the image processing program based at least inpart on the user input.

53. The at least one computer-readable storage medium of configuration50, wherein the information identifying the at least one imageprocessing technique comprises an indication that a newest imageprocessing technique is to be used in generating the still image datafrom the moving image data.

54. The at least one computer-readable storage medium of configuration53, wherein the information identifying the at least one imageprocessing technique comprises an indication that a newest version of animage processing program is to be used in generating the still imagedata from the moving image data.

55. The at least one computer-readable storage medium of configuration50, wherein the at least one image processing technique comprises animage processing technique selected from a group consisting of:reconfiguration-type super-resolution processing, learning-typesuper-resolution processing, and blurring removal processing.

56. The at least one computer-readable storage medium of configuration55, wherein the method further comprises:

capturing a moving image and thereby generating the moving image data;

transmitting the moving image data to the second apparatus.

57. The at least one computer-readable storage medium of configuration56, wherein capturing the moving image comprises capturing a medicalmoving image from an observation target.

58. The at least one computer-readable storage medium of configuration57, wherein capturing the medical moving image comprises using afunduscope to capture a moving image from the fundus of an eye of apatient.

59. The at least one computer-readable storage medium of configuration49, wherein the method further comprises:

upon receiving the still image data, notifying a user that the stillimage data is available.

60. The at least one computer-readable storage medium of configuration49, wherein the method further comprises:

displaying a still image to the user based on the still image data.

61. The at least one computer-readable storage medium of configuration49, wherein the method further comprises:

receiving user input via at least one input device; and

determining the at least one criterion based at least in part on theuser input.

62. The at least one computer-readable storage medium of configuration61, wherein the user input comprises time information, and whereindetermining the at least one criterion comprises determining the atleast one criterion based at least in part on the time information.

63. The at least one computer-readable storage medium of configuration61, wherein the user input comprises personal identificationinformation, and wherein determining the at least one criterioncomprises determining the at least one criterion based at least in parton the personal identification information.

64. The at least one computer-readable storage medium of configuration63, wherein the moving image data comprises medical moving image data,and wherein the personal identification information comprisesinformation identifying a patient who is a subject of the medical movingimage data.

65. An apparatus comprising at least one processor programmed to:

receive, via at least one network, a request from another apparatus forstill image data generated from moving image data, the requestcomprising at least one criterion;

use the at least one criterion in the request to obtain still image datagenerated from moving image data; and

respond to the request by transmitting the obtained still image data.

66. The apparatus of configuration 65, further comprising at least onestorage device, wherein the at least one processor is further programmedto:

receive the moving image data from the other apparatus; and

store the moving image data in the at least one storage device.

67. The apparatus of configuration 66, wherein the at least oneprocessor is further programmed to:

use a newest version of an image processing program to generate thestill image data from the moving image data.

68. The apparatus of configuration 65, further comprising at least onestorage device, wherein the at least one processor is further programmedto:

use the at least one criterion to retrieve the moving image data fromthe at least one storage device; and

generate the still image data based at least in part on the moving imagedata.

69. The apparatus of configuration 65, further comprising at least onestorage device, wherein the at least one processor is further programmedto:

use the at least one criterion to retrieve the still image data from theat least one storage device, the still image data having been previouslygenerated based at least in part on the moving image data.

70. The apparatus of configuration 69, wherein the still image data ispreviously generated still image data, and wherein the at least oneprocessor is further programmed to:

determine whether a new image processing technique is available;

if it is determined that a new image processing technique is available,use the new image processing technique to generate new still image databased at least in part on the moving image data; and

replace the previously generated still image data with the new stillimage data.

71. The apparatus of configuration 65, wherein the request received fromthe other device comprises information identifying at least one imageprocessing technique, and wherein the at least one processor is furtherprogrammed to:

use the identified at least one image processing technique to generatethe still image data based at least in part on the moving image data.

72. The apparatus of configuration 71, wherein the informationidentifying the at least one image processing technique comprises anidentifier for a version of an image processing program, and wherein theat least one processor is further programmed to:

determine whether the identified version of the image processing programis available; and

if it is determined that the identified version of the image processingprogram is not available, use a nearest available version of the imageprocessing program to generate the still image data from the movingimage data.

73. The apparatus of configuration 71, wherein the at least one imageprocessing technique comprises an image processing technique selectedfrom a group consisting of: reconfiguration-type super-resolutionprocessing, learning-type super-resolution processing, and blurringremoval processing.

74. An apparatus comprising:

means for receiving, via at least one network, a request from anotherapparatus for still image data generated from moving image data, therequest comprising at least one criterion;

means for using the at least one criterion in the request to obtainstill image data generated from moving image data; and

means for responding to the request by transmitting the obtained stillimage data.

75. The apparatus of configuration 74, further comprising storage means,wherein the means for receiving a request is further configured to:

receive the moving image data from the other apparatus; and

store the moving image data in the storage means.

76. The apparatus of configuration 75, further comprising:

means for using a newest version of an image processing program togenerate the still image data from the moving image data.

77. The apparatus of configuration 74, further comprising storage means,wherein the means for using the at least one criterion is furtherconfigured to:

use the at least one criterion to retrieve the moving image data fromthe storage means; and

generate the still image data based at least in part on the moving imagedata.

78. The apparatus of configuration 74, further comprising storage means,wherein the means for using the at least one criterion is furtherconfigured to:

use the at least one criterion to retrieve the still image data from thestorage means, the still image data having been previously generatedbased at least in part on the moving image data.

79. The apparatus of configuration 78, wherein the still image data ispreviously generated still image data, and wherein the apparatus furthercomprises means for:

determining whether a new image processing technique is available;

if it is determined that a new image processing technique is available,using the new image processing technique to generate new still imagedata based at least in part on the moving image data; and

replacing the previously generated still image data with the new stillimage data.

80. The apparatus of configuration 74, wherein the request received fromthe other device comprises information identifying at least one imageprocessing technique, and wherein the means for using the at least onecriterion is further configured to:

use the identified at least one image processing technique to generatethe still image data based at least in part on the moving image data.

81. The apparatus of configuration 80, wherein the informationidentifying the at least one image processing technique comprises anidentifier for a version of an image processing program, and wherein themeans for using the at least one criterion is further configured to:

determine whether the identified version of the image processing programis available; and

if it is determined that the identified version of the image processingprogram is not available, use a nearest available version of the imageprocessing program to generate the still image data from the movingimage data.

82. The apparatus of configuration 80, wherein the at least one imageprocessing technique comprises an image processing technique selectedfrom a group consisting of: reconfiguration-type super-resolutionprocessing, learning-type super-resolution processing, and blurringremoval processing.

83. A method comprising acts of:

receiving, via at least one network, a request for still image datagenerated from moving image data, the request comprising at least onecriterion;

using the at least one criterion in the request to obtain still imagedata generated from moving image data; and

responding to the request by transmitting the obtained still image data.

84. The method of configuration 83, further comprising:

receiving the moving image data via the at least one network; and

storing the moving image data in at least one storage device.

85. The method of configuration 84, further comprising:

using a newest version of an image processing program to generate thestill image data from the moving image data.

86. The method of configuration 83, further comprising:

using the at least one criterion to retrieve the moving image data fromat least one storage device; and

generating the still image data based at least in part on the movingimage data.

87. The method of configuration 83, further comprising:

using the at least one criterion to retrieve the still image data fromat least one storage device, the still image data having been previouslygenerated based at least in part on the moving image data.

88. The method of configuration 87, wherein the still image data ispreviously generated still image data, and wherein the method furthercomprises:

determining whether a new image processing technique is available;

if it is determined that a new image processing technique is available,using the new image processing technique to generate new still imagedata based at least in part on the moving image data; and

replacing the previously generated still image data with the new stillimage data.

89. The method of configuration 83, wherein the request received fromthe other device comprises information identifying at least one imageprocessing technique, and wherein the method further comprises:

using the identified at least one image processing technique to generatethe still image data based at least in part on the moving image data.

90. The method of configuration 89, wherein the information identifyingthe at least one image processing technique comprises an identifier fora version of an image processing program, and wherein the method furthercomprises:

determining whether the identified version of the image processingprogram is available; and

if it is determined that the identified version of the image processingprogram is not available, using a nearest available version of the imageprocessing program to generate the still image data from the movingimage data.

91. The method of configuration 89, wherein the at least one imageprocessing technique comprises an image processing technique selectedfrom a group consisting of: reconfiguration-type super-resolutionprocessing, learning-type super-resolution processing, and blurringremoval processing.

92. At least one computer-readable storage medium encoded withinstructions that, when executed by at least one processor, perform amethod comprising acts of:

receiving, via at least one network, a request for still image datagenerated from moving image data, the request comprising at least onecriterion;

using the at least one criterion in the request to obtain still imagedata generated from moving image data; and

responding to the request by transmitting the obtained still image data.

93. The at least one computer-readable storage medium of configuration92, wherein the method further comprises:

receiving the moving image data via the at least one network; and

storing the moving image data in at least one storage device.

94. The at least one computer-readable storage medium of configuration93, wherein the method further comprises:

using a newest version of an image processing program to generate thestill image data from the moving image data.

95. The at least one computer-readable storage medium of configuration92, wherein the method further comprises:

using the at least one criterion to retrieve the moving image data fromat least one storage device; and

generating the still image data based at least in part on the movingimage data.

96. The at least one computer-readable storage medium of configuration92, wherein the method further comprises:

using the at least one criterion to retrieve the still image data fromat least one storage device, the still image data having been previouslygenerated based at least in part on the moving image data.

97. The at least one computer-readable storage medium of configuration96, wherein the still image data is previously generated still imagedata, and wherein the method further comprises:

determining whether a new image processing technique is available;

if it is determined that a new image processing technique is available,using the new image processing technique to generate new still imagedata based at least in part on the moving image data; and

replacing the previously generated still image data with the new stillimage data.

98. The at least one computer-readable storage medium of configuration92, wherein the request received from the other device comprisesinformation identifying at least one image processing technique, andwherein the method further comprises:

using the identified at least one image processing technique to generatethe still image data based at least in part on the moving image data.

99. The at least one computer-readable storage medium of configuration98, wherein the information identifying the at least one imageprocessing technique comprises an identifier for a version of an imageprocessing program, and wherein the method further comprises:

determining whether the identified version of the image processingprogram is available; and

if it is determined that the identified version of the image processingprogram is not available, using a nearest available version of the imageprocessing program to generate the still image data from the movingimage data.

100. The at least one computer-readable storage medium of configuration98, wherein the at least one image processing technique comprises animage processing technique selected from a group consisting of:reconfiguration-type super-resolution processing, learning-typesuper-resolution processing, and blurring removal processing.

101. A system comprising:

a first apparatus comprising at least one first processor programmed to:

transmit, via at least one network, a request to a second apparatus forstill image data generated from moving image data, the requestcomprising at least one criterion; and

the second apparatus, wherein the second apparatus comprises at leastone second processor programmed to:

receive, via the at least one network, the request for still image data;

use the at least one criterion in the request to obtain still image datagenerated from moving image data; and

respond to the request by transmitting the obtained still image data tothe first apparatus,

wherein the at least one first processor is further programmed to:

receive the obtained still image data from the second apparatus.

Various embodiments of the present technology can assume additionalconfigurations such as described below.

<Additional Configuration 1>

A server device comprising:

an image processing unit to generate still image data from moving imagedata stored in a storage unit, wherein a processing program can beautomatically updated or added thereto;

a search information receiving unit to receive search informationtransmitted from a terminal device;

an image transmission unit to transmit, to said terminal device, stillimage data generated by processing predetermined moving image data usinga predetermined processing program, such still image data correspondingto search information received by said search information receivingunit.

<Additional Configuration 2>

The server device according to Additional configuration 1, furthercomprising:

a cache unit to hold the still image data generated by said imageprocessing unit;

wherein

in the case that still image data corresponding to the searchinformation from said terminal device is held in said cache unit, saidimage transmitting unit removes the still image data from the cache unitand transmits to said terminal device.

<Additional Configuration 3>

The server device according to Additional configuration 2, wherein thestill image data, which is generated by processing the moving image datastored in said storage unit with the newest version of the processingprogram in said image processing unit, is held in said cache unit.

<Additional Configuration 4>

The server device according to Additional configuration 2, wherein thestill image data, which is generated by processing the moving image datastored in said storage unit with all of the processing programs in saidimage processing unit, is held in said cache unit.

<Additional Configuration 5>

The server device according to Additional configuration 2, wherein thestill image data transmitted in the past by said image transmitting unitto the terminal device corresponding to the search information from saidterminal device is held in said cache unit.

<Additional Configuration 6>

The server device according to Additional configuration 1, wherein firstinformation that identifies said moving image data and secondinformation that identifies said processing program are included in thesearch information received by said search information receiving unit;

and wherein said image transmitting unit transmits, to said terminaldevice, the still image data generated by processing the moving imagedata identified by said first information with a processing programidentified by said second information.

<Additional Configuration 7>

The server device according to Additional configuration 1, wherein saidstorage unit stores moving image data that is transmitted from aterminal device which is the same as or different from said terminaldevice.

<Additional Configuration 8>

The server device according to Additional configuration 1, wherein saidimage data is image data of a medical image.

<Additional Configuration 9>

An image transmitting method, comprising:

a step of receiving of search information transmitted from a terminaldevice; and

a step of transmitting, to said terminal device, of still image data,which is generated by processing predetermined moving image data with apredetermined processing program, corresponding to said searchinformation.

<Additional Configuration 10>

A program causing a computer to function as:

search information receiving means to receive search informationtransmitted from a terminal device; and

image transmitting means to transmit, to said terminal device, stillimage data, which is generated by processing predetermined moving imagedata with a predetermined processing program, corresponding to thesearch information received by said search information receiving means.

<Additional Configuration 11>

An image processing system, comprising:

a server device and terminal device connected via a network;

said server device further including

an image processing unit to generate still image data from moving imagedata stored in a storage unit, wherein a processing program can beautomatically updated or added thereto;

a search information receiving unit to receive search informationtransmitted from said terminal device; and

an image transmission unit to transmit, to said terminal device, stillimage data generated by processing predetermined moving image data usinga predetermined processing program, such still image data correspondingto search information received by said search information receivingunit; and

said terminal device further including

a search information transmitting unit to transmit said searchinformation to said server device; and

an image receiving unit to receive said still image data correspondingto said search information, which is transmitted from said serverdevice.

<Additional Configuration 12>

A terminal device, comprising:

a search information transmitting unit to transmit, to a server device,search information including first information that identifies movingimage data and second information that identifies a processing programto generate still image data from the moving image data; and

an image receiving unit to receive the still image data generated byprocessing predetermined moving image data with a predeterminedprocessing program, corresponding to said search information, said stillimage data having been transmitted from said server device.

<Additional Configuration 13>

The terminal device according to Additional configuration 12, furthercomprising:

a user interface unit to select, with said second information, whetherto identify the newest processing program or whether to identify aprocessing program corresponding to the moving image data identifiedwith said first information.

<Additional Configuration 14>

An image receiving method, comprising:

a step of transmitting, to a server device, search information includingfirst information that identifies moving image data and secondinformation that identifies a processing program to generate still imagedata from the moving image data; and

a step of receiving the still image data generated by processingpredetermined moving image data with a predetermined processing program,corresponding to said search information, said still image data havingbeen transmitted from said server device.

<Additional Configuration 15>

A program causing a computer to function as:

search information transmitting means to transmit, to a server device,search information including first information that identifies movingimage data and second information that identifies a processing programto generate still image data from the moving image data; and

image receiving means to receive the still image data generated byprocessing predetermined moving image data with a predeterminedprocessing program, corresponding to said search information, said stillimage data having been transmitted from said server device.

The phraseology and terminology used herein is for the purpose ofdescription and should not be regarded as limiting. The use of“including,” “comprising,” “having,” “containing,” “involving,” andvariations thereof, is meant to encompass the items listed thereafterand additional items. Use of ordinal terms such as “first, ” “second, ”“third, ” etc., in the claims to modify a claim element does not byitself connote any priority, precedence, or order of one claim elementover another or the temporal order in which acts of a method areperformed. Ordinal terms are used merely as labels to distinguish oneclaim element having a certain name from another element having a samename (but for use of the ordinal term), to distinguish the claimelements from each other. Having described several embodiments of theinvention in detail, various modifications and improvements will readilyoccur to those skilled in the art. Such modifications and improvementsare intended to be within the spirit and scope of the invention.Accordingly, the foregoing description is by way of example only, and isnot intended as limiting. The invention is limited only as defined bythe following claims and the equivalents thereto.

REFERENCE SIGNS LIST

10, 10A image processing system

110-1, 110-2, 110-3 fundus camera

120-1, 120-2, 120-3 display terminal unit

200, 200A server device

201 fundus moving image storage unit

202 fundus image searching unit

203 image processing unit

204 cache unit

300 network

The invention claimed is:
 1. A method implemented by an apparatus,comprising at least one processor, the method comprising acts of:transmitting, via at least one network, a request to another apparatusfor still medical image data generated from moving medical image data,the request comprising at least one criterion, the request furthercomprising information identifying at least one image processingtechnique for use in generating still medical image data from movingmedical image data; and receiving still medical image data matching theat least one criterion in the request, the still medical image databeing generated by applying, to moving image data, the at least oneimage processing technique identified in the request.
 2. The method ofclaim 1, wherein the at least one image processing technique comprises atechnique that processes a plurality of image frames from moving medicalimage data to produce a still medical image having improved imagequality.
 3. The method of claim 1, wherein the information identifyingthe at least one image processing technique comprises an identifier fora version of an image processing program for use in generating the stillmedical image data from the moving medical image data.
 4. The method ofclaim 3, further comprising acts of: receiving user input via at leastone input device; and selecting the version of the image processingprogram based at least in part on the user input.
 5. The method of claim2, wherein the information identifying the at least one image processingtechnique comprises an indication that a newest image processingtechnique is to be used in generating the still medical image data fromthe moving medical image data.
 6. The method of claim 5, wherein theinformation identifying the at least one image processing techniquecomprises an indication that a newest version of an image processingprogram be used in generating the still medical image data from themoving medical image data.
 7. The method of claim 1, further comprisingacts of: using at least one medical imaging device to capture a movingmedical image and thereby generate the moving medical image data; andtransmitting the moving medical image data to the other apparatus. 8.The method of claim 1, further comprising acts of: receiving user inputvia at least one input device; and determining the at least onecriterion based at least in part on the user input.
 9. The method ofclaim 8, wherein: time information is received from the user via the atleast one input device; and the at least one criterion is determinedbased at least in part on the time information.
 10. The method of claim8, wherein: personal identification information is received from theuser via the at least one input device; and the at least one criterionis determined based at least in part on the personal identificationinformation.
 11. An apparatus comprising at least one processorprogrammed to: receive, via at least one network, a request from anotherapparatus for still medical image data generated from moving medicalimage data, the request comprising at least one criterion, the requestfurther comprising information identifying at least one image processingtechnique for use in generating still medical image data from movingmedical image data; use the at least one criterion in the request toobtain still medical image data generated by applying the at least oneimage processing technique to at least one image frame from movingmedical image data; and respond to the request by transmitting theobtained still medical image data.
 12. The apparatus of claim 11,further comprising at least one storage device, wherein the at least oneprocessor is further programmed to: receive the moving medical imagedata from the other apparatus; and store the moving medical image datain the at least one storage device.
 13. The apparatus of claim 12,wherein the at least one processor is further programmed to: determine,based on the information identifying at least one image processingtechnique for use in generating still medical image data from movingmedical image data, that a newest version of an image processing programis to be used; identify a newest version of the image processingprogram; and use the newest version of the image processing program togenerate the still medical image data from the moving medical imagedata.
 14. The apparatus of claim 11, further comprising at least onestorage device, wherein the at least one processor is further programmedto: use the at least one criterion to retrieve the moving medical imagedata from the at least one storage device; and generate the stillmedical image data based at least in part on the moving medical imagedata.
 15. The apparatus of claim 11, further comprising at least onestorage device, wherein the at least one processor is further programmedto: use the at least one criterion to retrieve the still medical imagedata from the at least one storage device, the still medical image datahaving been previously generated based at least in part on the movingmedical image data.
 16. The apparatus of claim 15, wherein the stillmedical image data is previously generated still medical image data, andwherein the at least one processor is further programmed to: determinewhether a new image processing technique is available; if it isdetermined that a new image processing technique is available, use thenew image processing technique to generate new still medical image databased at least in part on the moving medical image data; and replace thepreviously generated still medical image data with the new still medicalimage data.
 17. The apparatus of claim 11, wherein the at least oneprocessor is further programmed to: apply the at least one imageprocessing technique to a plurality of image frames from the movingmedical image data to generate a still medical image having improvedimage quality.
 18. The apparatus of claim 17, wherein the informationidentifying the at least one image processing technique comprises anidentifier for a version of an image processing program, and wherein theat least one processor is further programmed to: determine whether theidentified version of the image processing program is available; and ifit is determined that the identified version of the image processingprogram is not available, use a nearest available version of the imageprocessing program to generate the still medical image data from themoving medical image data.
 19. The apparatus of claim 17, wherein the atleast one image processing technique comprises an image processingtechnique selected from a group consisting of: reconfiguration-typesuper-resolution processing, learning-type super-resolution processing,and blurring removal processing.
 20. A system comprising: a firstapparatus comprising at least one first processor programmed to:transmit, via at least one network, a request to a second apparatus forstill medical image data generated from moving medical image data, therequest comprising at least one criterion, the request furthercomprising information identifying at least one image processingtechnique for use in generating still medical image data from movingmedical image data; and the second apparatus, wherein the secondapparatus comprises at least one second processor programmed to:receive, via the at least one network, the request for still medicalimage data; use the at least one criterion in the request to obtainstill medical image data generated by applying the at least one imageprocessing technique to at least one image frame from moving medicalimage data; and respond to the request by transmitting the obtainedstill medical image data to the first apparatus, wherein the at leastone first processor is further programmed to: receive the obtained stillmedical image data from the second apparatus.